,
archaea,
algae,
protozoa and
animals.|alt=Six relatively large variously shaped organisms with dozens of small light-colored dots all against a dark background. Some of the organisms have antennae that are longer than their bodies.
Plankton (from Greek for
wanderers) are a diverse group of organisms that live in the
water column of large bodies of water but cannot swim against a current. As a result, they wander or drift with the currents.
Phytoplankton are the plant-like components of the plankton community ("phyto" comes from the Greek for
plant). They are
autotrophic (self-feeding), meaning they generate their own food and do not need to consume other organisms. Phytoplankton perform three crucial functions: they generate nearly half of the world atmospheric oxygen, they regulate ocean and atmospheric carbon dioxide levels, and they form the base of the marine
food web. When conditions are right,
blooms of phytoplankton algae can occur in surface waters. Phytoplankton are
r-strategists which grow rapidly and can double their population every day. The blooms can become toxic and deplete the water of oxygen. However, phytoplankton numbers are usually kept in check by the phytoplankton exhausting available nutrients and by grazing zooplankton. Phytoplankton consist mainly of microscopic photosynthetic
eukaryotes which inhabit the upper sunlit layer in all oceans. They need sunlight so they can photosynthesize. Most phytoplankton are single-celled algae, but other phytoplankton are bacteria and some are
protists. Phytoplankton include
cyanobacteria (above),
diatoms, various other types of
algae (red, green, brown, and yellow-green),
dinoflagellates,
euglenoids,
coccolithophorids,
cryptomonads,
chlorophytes,
prasinophytes, and
silicoflagellates. They form the base of the
primary production that drives the ocean
food web, and account for half of the current global primary production, more than the terrestrial forests. File:Phytoplankton Lake Chuzenji.jpg|Phytoplankton are the foundation of the ocean food chain File:Phytopla.jpg|They come in many shapes and sizes. File:Phytoplankton - the foundation of the oceanic food chain.jpg|
Colonial phytoplankton File:Prochlorococcus marinus 2.jpg|The cyanobacterium
Prochlorococcus accounts for much of the ocean's primary production File:Cyanobacterial Scum.JPG|Green
cyanobacteria scum washed up on a rock in California
Diatoms Diatoms form a (disputed) phylum containing about 100,000 recognised species of mainly unicellular algae. Diatoms generate about 20 per cent of the oxygen produced on the planet each year, and contribute nearly half of the organic material found in the oceans. File:Diatoms (248 05) Various diatoms.jpg|
Diatoms are one of the most common types of phytoplankton File:Diatom Helipelta metil.jpg|Their protective shells (frustles) are made of silicon File:Diatom - Triceratium favus.jpg File:Diatom2.jpg|They come in many shapes and sizes Diatoms are enclosed in protective silica (glass) shells called
frustules. Each frustule is made from two interlocking parts covered with tiny holes through which the diatom exchanges nutrients and wastes. File:Diatom algae Amphora sp.jpg|Silicified frustule of a pennate diatom with two overlapping halves File:Fjouenne sbrmvr012w 20070924163039 small.jpg|
Guinardia delicatula, a diatom responsible for
algal blooms in the North Sea and the English Channel File:Ископаемая диатомовая водоросль.jpg|Fossil diatom File:Pinnularia major.jpg|There are over 100,000 species of
diatoms which account for 50% of the ocean's primary production
Coccolithophores Coccolithophores are minute unicellular photosynthetic protists with two flagella for locomotion. Most of them are protected by a shell covered with ornate circular plates or scales called
coccoliths. The coccoliths are made from calcium carbonate. The calcite shells are important to the marine carbon cycle. The term coccolithophore derives from the Greek for a
seed carrying stone, referring to their small size and the coccolith stones they carry. Under the right conditions they bloom, like other phytoplankton, and can turn the ocean milky white. File:9Calcidiscus leptoporus, diploid, SEM, showing coccoliths.tif|
Coccolithophores have plates called
coccoliths File:Coccolithus pelagicus.jpg|
Coccolithus pelagicus ssp.
braarudii File:JRYSEM-247-05-azurapl.jpg|
Syracosphaera azureaplaneta, named after the BBC documentary series
The Blue Planet File:Emiliania huxleyi.jpg|The
coccolithophore Emiliania huxleyi File:Cwall99 lg.jpg|
Algae bloom of
Emiliania huxleyi off the southern coast of England File:Discoaster surculus 01 (cropped).jpg|Extinct fossil
Microbial rhodopsin . Phototrophic metabolism relies on one of three energy-converting pigments:
chlorophyll,
bacteriochlorophyll, and
retinal. Retinal is the
chromophore found in
rhodopsins. The significance of chlorophyll in converting light energy has been written about for decades, but phototrophy based on retinal pigments is just beginning to be studied. in
salt evaporation ponds coloured purple by
bacteriorhodopsin In 2000 a team of microbiologists led by
Edward DeLong made a crucial discovery in the understanding of the marine carbon and energy cycles. They discovered a gene in several species of bacteria responsible for production of the protein
rhodopsin, previously unheard of in bacteria. These proteins found in the cell membranes are capable of converting light energy to biochemical energy due to a change in configuration of the rhodopsin molecule as sunlight strikes it, causing the pumping of a
proton from inside out and a subsequent inflow that generates the energy. The archaeal-like rhodopsins have subsequently been found among different taxa, protists as well as in bacteria and archaea, though they are rare in complex
multicellular organisms. Research in 2019 shows these "sun-snatching bacteria" are more widespread than previously thought and could change how oceans are affected by global warming. "The findings break from the traditional interpretation of marine ecology found in textbooks, which states that nearly all sunlight in the ocean is captured by chlorophyll in algae. Instead, rhodopsin-equipped bacteria function like hybrid cars, powered by organic matter when available — as most bacteria are — and by sunlight when nutrients are scarce."
Redfield and f- ratios During the 1930s
Alfred C. Redfield found similarities between the composition of elements in phytoplankton and the major dissolved nutrients in the deep ocean. Redfield proposed that the ratio of carbon to nitrogen to phosphorus (106:16:1) in the ocean was controlled by the phytoplankton's requirements, as phytoplankton subsequently release nitrogen and phosphorus as they remineralize. This ratio has become known as the
Redfield ratio, and is used as a fundamental principle in describing the
stoichiometry of seawater and phytoplankton evolution. However, the Redfield ratio is not a universal value and can change with things like geographical latitude. Based on allocation of resources, phytoplankton can be classified into three different growth strategies: survivalist, bloomer and generalist. Survivalist phytoplankton has a high N:P ratio (>30) and contains an abundance of resource-acquisition machinery to sustain growth under scarce resources. Bloomer phytoplankton has a low N:P ratio ( File:Copepod 2 with eggs.jpg|
Copepods eat phytoplankton. This one is carrying eggs. File:Tintinnid ciliate Favella.jpg|
Tintinnid ciliate
Favella Many species of
protozoa (
eukaryotes) and
bacteria (
prokaryotes) prey on other microorganisms; the feeding mode is evidently ancient, and evolved many times in both groups. Among freshwater and marine
zooplankton, whether single-celled or multi-cellular, predatory grazing on
phytoplankton and smaller zooplankton is common, and found in many species of
nanoflagellates,
dinoflagellates,
ciliates,
rotifers, a diverse range of
meroplankton animal larvae, and two groups of crustaceans, namely
copepods and
cladocerans.
Radiolarians Radiolarians are unicellular predatory
protists encased in elaborate globular shells usually made of silica and pierced with holes. Their name comes from the Latin for "radius". They catch prey by extending parts of their body through the holes. As with the silica frustules of diatoms, radiolarian shells can sink to the ocean floor when radiolarians die and become preserved as part of the
ocean sediment. These remains, as
microfossils, provide valuable information about past oceanic conditions. File:Mikrofoto.de-Radiolarien 6.jpg|Like diatoms, radiolarians come in many shapes File:Theocotylissa ficus Ehrenberg - Radiolarian (34638920262).jpg|Also like diatoms, radiolarian shells are usually made of silicate File:Acantharian radiolarian Xiphacantha (Haeckel).jpg|However
acantharian radiolarians have shells made from
strontium sulfate crystals File:Spherical radiolarian 2.jpg|Cutaway schematic diagram of a spherical radiolarian shell File:Cladococcus abietinus.jpg|
Cladococcus abietinus Foraminiferans Like radiolarians,
foraminiferans (
forams for short) are single-celled predatory protists, also protected with shells that have holes in them. Their name comes from the Latin for "hole bearers". Their shells, often called
tests, are chambered (forams add more chambers as they grow). The shells are usually made of calcite, but are sometimes made of
agglutinated sediment particles or
chiton, and (rarely) of silica. Most forams are benthic, but about 40 species are planktic. They are widely researched with well established fossil records which allow scientists to infer a lot about past environments and climates. A number of forams are
mixotrophic (
see below). These have unicellular
algae as
endosymbionts, from diverse lineages such as the
green algae,
red algae,
golden algae,
diatoms, and
dinoflagellates. Some forams are
kleptoplastic, retaining
chloroplasts from ingested algae to conduct
photosynthesis.
Amoeba Amoeba can be shelled (
testate) or naked. File:Cyphoderia ampulla - Testate amoeba - 160x (14997391862).jpg|
Testate amoeba,
Cyphoderia sp. File:Arcella sp.jpg|Shell or test of a
testate amoeba,
Arcella sp. File:Collection Penard MHNG Specimen 533-2-1 Pamphagus granulatus.tif|
Xenogenic testate amoeba covered in diatoms (from Penard's Amoeba Collection) File:Chaos carolinense.jpg|Naked amoeba,
Chaos sp. File:Amoeba proteus 2.jpg|Naked amoeba showing food vacuoles and ingested diatom
Ciliates File:Oxytricha chlorelligera - 400x (10403483023).jpg|
Oxytricha chlorelligera File:Stylonychia putrina - 160x - II (13215594964).jpg|
Stylonychia putrina File:Holophyra ovum - 400x (9836710085).jpg|
Holophyra ovum File:Mesodinium rubrum.jpg|
Mesodinium rubrum produce deep red blooms using enslaved chloroplasts from their algal prey|alt=Mesodinium rubrum produce deep red blooms using enslaved chloroplasts from their algal prey File:Mikrofoto.de-Blepharisma japonicum 15.jpg|
Blepharisma japonicum File:Из жизни инфузорий.webm|Several taxa of ciliates interacting File:Blepharisma americana.ogv|
Blepharisma americanum swimming in a drop of pond water with other microorganisms
Mixotrophs A
mixotroph is an organism that can use a mix of different
sources of energy and carbon, instead of having a single trophic mode on the continuum from complete
autotrophy at one end to
heterotrophy at the other. It is estimated that mixotrophs comprise more than half of all microscopic plankton. There are two types of eukaryotic mixotrophs: those with their own
chloroplasts, and those with
endosymbionts—and others that acquire them through
kleptoplasty or by enslaving the entire phototrophic cell. The distinction between plants and animals often breaks down in very small organisms. Possible combinations are
photo- and
chemotrophy,
litho- and
organotrophy,
auto- and
heterotrophy or other combinations of these. Mixotrophs can be either
eukaryotic or
prokaryotic. They can take advantage of different environmental conditions. Recent studies of marine microzooplankton found 30–45% of the ciliate abundance was mixotrophic, and up to 65% of the amoeboid, foram and radiolarian
biomass was mixotrophic. It has the ability to form floating colonies, where hundreds of cells are embedded in a gel matrix, which can increase massively in size during
blooms. As a result,
Phaeocystis is an important contributor to the marine
carbon and
sulfur cycles.
Phaeocystis species are endosymbionts to
acantharian radiolarians. File:Tintinnid ciliate Favella.jpg|
Tintinnid ciliate
Favella File:Euglena mutabilis - 400x - 1 (10388739803) (cropped).jpg|
Euglena mutabilis, a photosynthetic
flagellate File:Stichotricha secunda - 400x (14974779356).jpg|
Zoochlorellae (green) living inside the
ciliate Stichotricha secunda Dinoflagellates Dinoflagellates are part of the
algae group, and form a phylum of unicellular flagellates with about 2,000 marine species. The name comes from the Greek "dinos" meaning
whirling and the Latin "flagellum" meaning a
whip or
lash. This refers to the two whip-like attachments (flagella) used for forward movement. Most dinoflagellates are protected with red-brown, cellulose armour. Like other phytoplankton, dinoflagellates are
r-strategists which under right conditions can
bloom and create
red tides.
Excavates may be the most basal flagellate lineage. Some species are
endosymbionts of marine animals and other protists, and play an important part in the biology of
coral reefs. Others predate other protozoa, and a few forms are parasitic. Many dinoflagellates are
mixotrophic and could also be classified as phytoplankton. The toxic dinoflagellate
Dinophysis acuta acquire chloroplasts from its prey. "It cannot catch the cryptophytes by itself, and instead relies on ingesting ciliates such as the red
Myrionecta rubra, which sequester their chloroplasts from a specific cryptophyte clade (Geminigera/Plagioselmis/Teleaulax)". The nassellarian provides
ammonium and
carbon dioxide for the dinoflagellate, while the dinoflagellate provides the nassellarian with a mucous membrane useful for hunting and protection against harmful invaders. There is evidence from
DNA analysis that dinoflagellate symbiosis with radiolarians evolved independently from other dinoflagellate symbioses, such as with
foraminifera. Some dinoflagellates are
bioluminescent. At night, ocean water can light up internally and
sparkle with blue light because of these dinoflagellates. Bioluminescent dinoflagellates possess
scintillons, individual
cytoplasmic bodies which contain
dinoflagellate luciferase, the main enzyme involved in the luminescence. The luminescence, sometimes called
the phosphorescence of the sea, occurs as brief (0.1 sec) blue flashes or sparks when individual scintillons are stimulated, usually by mechanical disturbances from, for example, a boat or a swimmer or surf. File:Ceratium tripos.jpg|
Tripos muelleri is recognisable by its U-shaped horns File:Archives de zoologie expérimentale et générale (1920) (20299351186).jpg|
Oodinium, a genus of
parasitic dinoflagellates, causes
velvet disease in fish File:Karenia brevis.jpg|
Karenia brevis produces red tides highly toxic to humans File:Algal bloom(akasio) by Noctiluca in Nagasaki.jpg|
Red tide File:Noctiluca scintillans unica.jpg|
Noctiluca scintillans, a bioluminescent dinoflagellate ==Marine sediments and microfossils==